JP5979199B2 - Light emitting device, light source device, and projector using the light source device - Google Patents

Description

  The present invention relates to a light emitting device, a light source device including a plurality of light emitting devices, and a projector incorporating the light source device.

  2. Description of the Related Art Today, a projector as an image projection apparatus that projects a screen of a personal computer, a video image, an image based on image data stored in a memory card or the like onto a screen is widely used. This projector focuses light emitted from a light source on a micromirror display element called DMD (digital micromirror device) or a liquid crystal plate, and displays a color image on a screen.

  Conventionally, projectors using a high-intensity discharge lamp as the light source have been the mainstream of such projectors, but in recent years, developments have been made to use solid-state light emitting elements such as red, green, and blue light emitting diodes and laser diodes as the light source. Has been made. Furthermore, various light-emitting devices using phosphors that absorb excitation light emitted from a solid light-emitting element and convert the light into a predetermined wavelength band have been developed. For example, in JP-A-2005-294185 (Patent Document 1) and JP-A-2005-267927 (Patent Document 2), a light emitting element as an excitation energy source and a phosphor are provided, and the excitation energy source and the phosphor A light-emitting device having a heat radiating part such as a refrigerant channel is proposed.

JP 2005-294185 A JP 2005-267927 A

  The light emitting device described in the above document can suppress the temperature rise of the phosphor by forming the heat radiating portion so as to be in contact with the phosphor between the phosphor and the excitation energy source. However, since the phosphor is indirectly cooled, there is a problem that a sufficient cooling effect cannot be expected.

  In addition, the structure having the refrigerant flow path as the heat radiating portion must also be formed of light-transmitting glass or resin, and glass having low thermal conductivity is disposed between the phosphor and the refrigerant. Therefore, there has been a problem that the phosphor cannot be efficiently cooled. Furthermore, since the structure having the refrigerant flow path is disposed on the optical path of the excitation energy source, there is a problem in that the amount of excitation light applied to the phosphor is reduced.

The present invention has been made in view of such problems of the prior art, an object of a light emitting device capable of maintaining the performance over a long period, and a light source device, to provide a projector .

The light emitting device of the present invention comprises a phosphor that emits light in a predetermined wavelength region upon receiving an excitation light beam, an excitation energy source that irradiates the phosphor with an excitation light beam, and an excitation light beam from the excitation energy source. excitation light transmission portion incident, and said a case having a luminous transmission portion the phosphor emits wavelength region light emitted, wherein the phosphor is applied in the case, the refrigerant to the phosphor surface The inlet of the refrigerant is formed at a predetermined angle so that

According to the present invention, it is possible to provide a light emitting device capable of maintaining the performance over a long period, and a light source device, a projector.

1 is a perspective view showing an external appearance of a projector according to an embodiment of the invention. It is a figure which shows the functional circuit block of the projector which concerns on the Example of this invention. 1 is a schematic plan view showing an internal structure of a projector according to an embodiment of the invention. It is a plane schematic diagram of the light source device which concerns on the Example of this invention. It is a plane schematic diagram which shows the partial cross section of the light-emitting device which concerns on the Example of this invention. It is a plane schematic diagram which shows the partial cross section of the light-emitting device which concerns on the modification of this invention. It is a plane schematic diagram which shows the partial cross section of the light-emitting device which concerns on the other modification of this invention.

  A mode for carrying out the present invention will be described. The projector 10 includes a light source device 63, a display element 51, a cooling fan, a light source side optical system 62 that guides light from the light source device 63 to the display element 51, and an image emitted from the display element 51 on a screen. A projection-side optical system 90 for projecting and projector control means for controlling the light source device 63 and the display element 51 are provided.

  The light source device 63 is a light emitting device in which the excitation energy source 72 is a light emitting diode or a laser light emitter that emits light in the ultraviolet wavelength region (ultraviolet light) having a shorter wavelength than red, green, and blue wavelength region light. The three light-emitting devices 64 emit red wavelength light in the case 130 and the red light-emitting device 64R in which the red phosphor 131 that emits light in the red wavelength region is disposed, and the case 130 emits light in the green wavelength region. A green light emitting device 64G in which the green phosphor 131 is arranged and a blue light emitting device 64B in which a blue phosphor 131 that emits light in the blue wavelength band is arranged in the case 130 are configured. A reflection mirror 140 and a dichroic mirror 141 are provided as an optical axis conversion device that converts the direction of the optical axis of the light beam emitted from 64 to match.

  The light-emitting device 64 includes a phosphor 131 that emits light in a predetermined wavelength range by receiving and absorbing an excitation beam, an excitation energy source 72 that irradiates the phosphor 131 with an excitation beam, and the excitation A case 130 having an excitation light transmissive part 132 for receiving an excitation light beam from the energy source 72 and a light emission transmissive part 133 for emitting light in a wavelength region emitted from the phosphor 131, a refrigerant 135, and the refrigerant 135 are circulated. And a circulating water pipe 138 as a circulation path connected to the case 130 and the pump 136.

  The phosphor 131 is arranged in a position where the jet of the refrigerant 135 flowing into the case 130 hits both surfaces of the phosphor 131. Specifically, the phosphor 131 is arranged at the center of the case 130 so as to divide the case 130 into an excitation light transmission part 132 side and a light emission transmission part 133 side. The inlet / outlet of the circulating water pipe 138 is provided on each of the excitation light transmitting part 132 side and the light emitting / transmitting part 133 side, and the inlet 135 of the circulating water pipe 138 is arranged in the center with the refrigerant 135 ejected from the inlet part. It is formed so as to hit the phosphor 131.

  That is, in this phosphor 131, the refrigerant 135 ejected from the inlet of the circulating water pipe 138 provided on the excitation light transmission part 132 side and the light emission transmission part 133 side is connected to the surface on the excitation light transmission part 132 side and the light transmission part 133. It arrange | positions so that it may touch both surfaces of a side surface directly, and can cool effectively.

  In the light emitting device 64, a reflection layer 134 is formed on the inner surface of the case 130 excluding the excitation light transmitting portion 132 and the light emitting transmitting portion 133.

  Further, a dichroic layer 132a that transmits excitation light and reflects light in the wavelength region emitted from the phosphor 131 is formed in the excitation light transmission part 132 of the case 130. A dichroic layer 133a that reflects the working light and transmits the wavelength band light emitted from the phosphor 131 is formed.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is an external perspective view of the projector 10. In this embodiment, left and right indicate the left and right direction with respect to the projection direction, and front and rear indicate the front and rear direction with respect to the traveling direction of the light beam. As shown in FIG. 1, the projector 10 has a substantially rectangular parallelepiped shape, and has a lens cover 19 that covers the projection port on the side of the front panel 12 that is a side plate in front of the main body case. Is provided with a plurality of exhaust holes 17. Further, although not shown, an Ir receiver for receiving a control signal from the remote controller is provided.

  In addition, a key / indicator unit 37 is provided on the top panel 11 which is a main body case. The key / indicator unit 37 includes a power switch key, a power indicator for notifying power on / off, and projection on / off. There are arranged keys and indicators such as a projection switch key for switching, an overheat indicator for notifying when a light source device, a display element, a control circuit or the like is overheated.

  In addition, on the back side of the main body case, there are provided various terminals 20 such as an input / output connector section and a power adapter plug for providing a USB terminal, a D-SUB terminal for image signal input, an S terminal, an RCA terminal, etc. on the rear panel. Yes. A plurality of intake holes 18 are formed in the vicinity of the lower portion of the right side panel 14 which is a side plate of the main body case (not shown) and the left side panel 15 which is the side plate shown in FIG.

  Next, projector control means of the projector 10 will be described with reference to the block diagram of FIG. The projector control means includes a control unit 38, an input / output interface 22, an image conversion unit 23, a display encoder 24, a display drive unit 26, and the like. Image signals of various standards input from the input / output connector unit 21 are input / output. The image conversion unit 23 converts the image signal into a predetermined format suitable for display via the interface 22 and the system bus (SB), and outputs the image signal to the display encoder 24.

  The display encoder 24 develops and stores the input image signal in the video RAM 25, generates a video signal from the stored contents of the video RAM 25, and outputs the video signal to the display driver 26.

  The display driving unit 26 drives the display element 51, which is a spatial light modulation element (SOM), at an appropriate frame rate corresponding to the image signal output from the display encoder 24, and is emitted from the light source device 63. A light beam is incident on the display element 51 via the light source side optical system, thereby forming an optical image with the reflected light of the display element 51, and an image is displayed on a screen (not shown) via a projection system lens group serving as a projection side optical system. Is projected and displayed. The movable lens group 97 of the projection side optical system is driven by the lens motor 45 for zoom adjustment and focus adjustment.

  Further, the image compression / decompression unit 31 performs a recording process in which the luminance signal and the color difference signal of the image signal are data-compressed by a process such as ADCT and Huffman coding, and are sequentially written in a memory card 32 which is a detachable recording medium. Further, the image compression / decompression unit 31 reads out the image data recorded on the memory card 32 in the reproduction mode, decompresses individual image data constituting a series of moving images in units of one frame, and converts the image data into the image conversion unit 23. Is output to the display encoder 24 and the processing for enabling the display of a moving image or the like based on the image data stored in the memory card 32 is performed.

  The control unit 38 controls operation of each circuit in the projector 10, and includes a ROM that stores operation programs such as a CPU and various settings fixedly, and a RAM that is used as a work memory. .

  An operation signal of a key / indicator unit 37 composed of a main key and an indicator provided on the upper panel 11 of the main body case is directly sent to the control unit 38, and a key operation signal from the remote controller is sent to the Ir receiving unit 35. , And the code signal demodulated by the Ir processor 36 is output to the controller 38.

  Note that an audio processing unit 47 is connected to the control unit 38 via a system bus (SB). The sound processing unit 47 includes a sound source circuit such as a PCM sound source, converts the sound data into analog in the projection mode and the playback mode, and drives the speaker 48 to emit loud sounds.

  Further, the control unit 38 causes the light source control circuit 41 to time-division-control the light sources 72 of the respective light emitting devices that emit light in the red, green, and blue wavelength bands in accordance with the image signal. Further, the control unit 38 causes the cooling fan drive control circuit 43 to perform temperature detection using a plurality of temperature sensors provided in the light source device 63 and the like, and controls the rotation speed of the cooling fan based on the temperature detection result. Further, the control unit 38 causes the cooling fan drive control circuit 43 to keep the cooling fan rotating even after the projector body is turned off by a timer or the like, and further turns off the projector body depending on the result of temperature detection by the temperature sensor. Control is also performed.

  These ROM, RAM, IC and circuit elements are incorporated into a control circuit board 103 and a power supply circuit block 101 as a main control board, which will be described later, and the control circuit board 103 as a main control board of the control system and the power system The light source control circuit board 102 to which the power supply circuit block 101 and the like are attached is formed separately.

  Next, the internal structure of the projector 10 will be described. FIG. 3 is a schematic plan view showing the internal structure of the projector 10. As shown in FIG. 3, the projector 10 has a light source control circuit board 102 to which a power circuit block 101 and the like are attached in the vicinity of the right panel 14, and a sirocco fan type blower 110 is arranged in the approximate center. A control circuit board 103 is disposed near 110, a light source device 63 is disposed near the front panel 12, and an optical system unit 70 is disposed near the left panel 15. Further, the projector 10 is airtightly divided into an intake side space chamber 121 on the rear panel 13 side and an exhaust side space chamber 122 on the front panel 12 side by a partition wall 120 in the housing, and the blower 110 has a suction port 111 is disposed in the intake side space chamber 121 and the discharge port 113 is positioned at the boundary between the exhaust side space chamber 122 and the intake side space chamber 121.

  The optical system unit 70 includes an illumination side block 78 located in the vicinity of the light source device 63, an image generation block 79 located on the back panel 13 side, and a projection side block located between the illumination side block 78 and the left panel 15. It is a substantially U-shape composed of 80 and 3 blocks.

  The illumination side block 78 includes a part of the light source side optical system 62 that guides the light emitted from the light source device 63 to the display element 51 provided in the image generation block 79. As the light source side optical system 62 included in the illumination side block 78, the light guide device 75 that converts the light beam emitted from the light source device 63 into a light beam having a uniform intensity distribution, and condenses light transmitted through the light guide device 75. There is a condensing lens.

  The image generation block 79 includes, as the light source side optical system 62, an optical axis changing mirror 74 that changes the optical axis direction of the light beam emitted from the light guide device 75, and light reflected by the optical axis changing mirror 74 as a display element. A plurality of condensing lenses for condensing on 51 and an irradiation mirror 84 for irradiating the display element 51 with a light beam transmitted through these condensing lenses at a predetermined angle. Further, the image generation block 79 includes a DMD serving as a display element 51, and a display element cooling device 53 for cooling the display element 51 is disposed on the rear panel 13 side of the display element 51. Prevents high temperatures.

  The projection-side block 80 includes a lens group of the projection-side optical system 90 that emits light that is reflected by the display element 51 and forms an image to the screen. The projection-side optical system 90 includes a fixed lens group 93 built in a fixed lens barrel and a movable lens group 97 built in a movable lens barrel, and is a variable focus lens having a zoom function, and is movable by a lens motor. Zoom adjustment and focus adjustment are enabled by moving the lens group 97.

  Further, in the internal structure of the projector 10, members having a temperature lower than that of the light source device 63 are arranged in the intake side space chamber 121. Specifically, the light source control circuit board 102 and the blower 110 are arranged. A control circuit board 103, an image generation block 79 of the optical system unit 70, a projection side block 80 of the optical system unit 70, and a condenser lens in the illumination side block 78 of the optical system unit 70. .

  On the other hand, in the exhaust-side space chamber 122, a light source device 63 that has a relatively high temperature, a light guide device 75 provided in the illumination-side block 78 of the optical system unit 70, and an exhaust temperature reducing device 114 are arranged.

  The light source device 63 according to the present invention includes three light-emitting devices 64 that receive excitation light from the excitation energy source 72 and emit light having different wavelength ranges to the light guide device 75. Specifically, a red phosphor that emits red wavelength band light is arranged and a red light emitting device 64R that emits red wavelength band light and a green phosphor that emits green wavelength band light are arranged. A green light emitting device 64G that emits light in the wavelength region of green and a blue light emitting device 64B that emits light in the wavelength region of blue by arranging a blue phosphor that emits light in the blue wavelength region.

  Each light emitting device 64 is arranged so that the optical axis of the light emitted from the light emitting device 64 is orthogonal to the optical axis of the light guide device 75. A red light emitting device 64R is disposed near the blower outlet 113, a blue light emitting device 64B is disposed near the front panel 12, and a green light emitting device 64G is disposed between the red light emitting device 64R and the blue light emitting device 64B. Has been.

  Each light emitting device 64 is provided with an excitation energy source 72. The excitation light from the excitation energy source 72 is irradiated on the phosphors included in each light emitting device 64, so that light in the wavelength region of each color is emitted. Is emitted from the light emitting device 64. The excitation energy source 72 includes a light emitting diode or laser emitter that emits violet wavelength light or ultraviolet wavelength light (ultraviolet light) that is visible light having a shorter wavelength than red, green, and blue wavelength light. It is what is done.

  In addition, it is not limited to the case where all the excitation energy sources 72 have the same specification, and any excitation light beam capable of emitting light in a predetermined wavelength range from each phosphor may be used. The red and green light emitting devices 64R and 64G may employ an excitation energy source 72 that can emit blue wavelength band light having a shorter wavelength than the red and green wavelength bands as excitation light. Further, a plurality of types of excitation energy sources 72 may be arranged in each light emitting device 64, and may be used by switching according to the situation.

  In addition, as shown in FIG. 4, the light source device 63 includes three light emitting devices 64 that generate light of a predetermined wavelength range of red, green, and blue, which are the three primary colors of light, and light beams emitted from the respective light emitting devices 64. A condensing optical system including a reflection mirror 140, a dichroic mirror 141, and a lens as an optical axis conversion device for converting the optical axis of the bundle is provided.

  Although this condensing optical system can adopt various configurations, in this embodiment, an optical axis conversion device is arranged in the light emitting direction of each light emitting device 64, and each light emitting device 64 The direction of the optical axis of the light bundle is made to coincide with the optical axis of the light guide device 75 and converted by 90 degrees. Specifically, a first dichroic mirror 141a that reflects red light and transmits light other than red light is disposed at a position where the optical axis of the red light emitting device 64R and the light guide device 75 intersects, and reflects green light. A second dichroic mirror 141b that transmits light other than green light is arranged at a position where the green light emitting device 64G and the optical axis of the light guide device 75 intersect, and a reflecting mirror 140 that reflects light guides the light from the blue light emitting device 64B. It is arranged at a position where the optical axis of the device 75 intersects.

  The condensing optical system includes a lens group 148 as a condensing lens and a convex lens 163 for condensing and guiding the light flux from each light emitting device 64 to the light guide device 75, and further, red, green The light guide device incident lens 164 for condensing the blue light beam on the incident surface of the light guide device 75 is provided.

  By configuring the condensing optical system in this way, the red light emitted from the red light emitting device 64R is condensed by the lens group 148 and irradiated to the convex lens 163, and the light condensed by the convex lens 163 is the first light. After being reflected by the dichroic mirror 141a, the light is condensed on the incident surface of the light guide device 75 by the light guide device incident lens 164.

  Further, the green light emitted from the green light emitting device 64G is collected by the lens group 148, enters the second dichroic mirror 141b, is reflected by the second dichroic mirror 141b, and then collected by the convex lens 163. After being irradiated onto the dichroic mirror 141a and transmitted through the first dichroic mirror 141a, the light is condensed on the incident surface of the light guide device 75 by the light guide device incident lens 164.

  Then, the blue light emitted from the blue light emitting device 64B is collected by the lens group 148 and applied to the reflection mirror 140, reflected by the reflection mirror 140, and then collected by the convex lens 163 to the second dichroic mirror 141b. After being irradiated and transmitted through the second dichroic mirror 141b, the light is further collected by the convex lens 163, irradiated to the first dichroic mirror 141a, transmitted through the first dichroic mirror 141a, and then guided by the light guide device incident lens 164. The light is collected on 75 incident surfaces.

  Therefore, the three light emitting devices 64 of the light source device 63 are time-division controlled by the light source control circuit 41, so that the light bundles in the predetermined wavelength region are sequentially incident on the light guide device 75 and are incident on the light guide device 75. The light beam is guided to the display element 51 by the light source side optical system 62. Thus, the display element 51 displays the light of each color in a time-sharing manner according to the data in accordance with the irradiation timing of each excitation energy source 72, so that a color image can be generated on the screen via the projection-side optical system 90. it can.

  Next, the structure of the light emitting device 64 that is the red light emitting device 64R, the green light emitting device 64G, and the blue light emitting device 64B will be described. The light emitting device 64 includes a rectangular parallelepiped case 130, a circulating water pipe 138 as a circulation path connected to both ends of the case 130, a pump 136 for circulating the refrigerant sealed in the case 130 and the circulating water pipe 138, have. The refrigerant is a fluid such as water or a fluorine-based antifreeze liquid having high light transmittance.

  Further, the circulating water system of the light emitting device 64 is provided with a cooler 137 for cooling the refrigerant. The cooler 137 is, for example, an air-cooled radiator (heat radiator), and is configured to be able to cool the refrigerant by blowing air from a cooling fan of the projector 10.

  That is, in the light emitting device 64, the circulating water pipe 138 is connected to the case 130, the pump 136, and the cooler 137 to constitute a circulating water system, whereby the refrigerant is cooled by the cooler 137 and the refrigerant is circulated by the pump 136. Thus, it is possible to always supply the low-temperature refrigerant to the case 130.

  The light emitting device 64 is a refrigerant that is excited by receiving and absorbing an excitation light beam and that emits light having a predetermined wavelength range and is disposed at a predetermined position in the case 130, and flows into the case 130. It comes to be in direct contact with.

  Specifically, as shown in FIG. 5, the phosphor 131 is disposed on the excitation light transmitting part 132 of the case 130, and the inlet part of the circulating water pipe 138 is formed at a predetermined angle, so that the inflow The jet flow of the refrigerant 135 that hits the surface of the phosphor 131 obliquely makes it possible to sufficiently remove heat from the surface of the phosphor 131. It should be noted that the phosphor 131 may be cooled by introducing the flow of the refrigerant 135 into the case 130 without hitting the surface of the phosphor 131 to create a flow around the phosphor 131. More effective cooling can be achieved by applying the jet stream of the above to the surface of the phosphor 131.

  In the case 130 of the light-emitting device 64, an excitation light transmitting part 132 for entering the excitation light from the excitation energy source 72 is disposed on the surface on the excitation energy source 72 side, and the fluorescent light is disposed on the opposite surface opposite to the case 130. A light-emitting transmission part 133 that emits light in a wavelength region emitted from the body 131 is disposed.

  The excitation light transmitting portion 132 and the light emitting transmitting portion 133 are rectangular plates having light transmittance such as glass, and are held by a cover plate having a rectangular opening narrower than the rectangular plate. Further, the inside of the case 130 is watertight by an O-ring 139 attached to the end portion of the side plate.

  In addition, the excitation light transmitting part 132 is formed with a dichroic layer 132a that transmits the excitation light and reflects the wavelength band light emitted from the phosphor 131, and the light transmitting part 133 reflects the excitation light. In addition, a dichroic layer 133a that transmits light in the wavelength band emitted from the phosphor 131 is formed. Note that a non-reflective coating layer (not shown) is formed on the incident surface side of the excitation light beam 132 in the excitation light transmission part 132 by coding.

  A reflection layer 134 that reflects light is formed on the entire inner surface of the case 130 excluding the excitation light transmission part 132 and the light emission transmission part 133. The reflective layer 134 may be formed by finishing the member of the case 130 into a mirror surface using metal or performing silver vapor deposition or the like.

  Next, the excitation light beam emitted from the excitation energy source 72 and the light beam emitted from the case 130 and incident on the light guide device 75 will be described. When the excitation light beam is irradiated from the excitation energy source 72 to the excitation light beam transmitting part 132 of the case 130, the excitation light beam passes through the non-reflective coating layer on the incident surface of the excitation light beam transmission part 132 on the excitation energy source 72 side. The light is transmitted through the excitation light transmitting part 132 with almost no reflection.

  Then, the excitation light beam that has passed through the excitation light beam transmitting portion 132 passes through the dichroic layer 132a and is applied to the phosphor 131. The phosphor 131 absorbs the excitation light and emits light in a predetermined wavelength range in all directions. That is, red wavelength band light is emitted from the red phosphor 131 of the red light emitting device 64R, green wavelength band light is emitted from the green phosphor 131 of the green light emitting device 64G, and the blue phosphor of the blue light emitting device 64B. 131 emits blue wavelength band light.

  The light emitted from the phosphor 131 to the light transmission part 133 side passes through the light transmission part 133 and enters the light guide device 75 as it is through the condensing optical system, and is a part other than the light transmission part 133. The light emitted to the inner surface of the case 130 and the excitation light transmitting portion 132 is reflected by the reflective layer 134 on the inner surface of the case 130 and the dichroic layer 132a of the excitation light transmitting portion 132, and the reflected light is transmitted through the light emitting transmission portion 133. Most of the light is incident on the light guide device 75 as light emitted from the light emitting device 64.

  Further, the excitation light beam that has passed through the excitation light beam transmission part 132 and directly emitted to the light emission transmission part 133 is reflected by the dichroic layer 133a and absorbed by the phosphor 131. In addition, the excitation light irradiated on the inner surface of the case 130 is also reflected by the reflective layer 134 and absorbed by the phosphor 131. As a result, the light emitting device 64 can effectively emit bright light, and a large amount of light can be incident on the light guide device 75.

  As described above, the light emitting device 64 can effectively cool the phosphor 131 by disposing the phosphor 131 in the case 130 and directly contacting the circulating low-temperature refrigerant 135. it can. Furthermore, a more effective cooling effect can be expected by arranging the phosphor 131 at a position where the jet of the refrigerant 135 hits the surface of the phosphor 131. That is, the light emitting device 64 can improve the heat transfer rate by forced convection and perform efficient cooling. Further, since the light emitting device 64 can cool the refrigerant 135 whose temperature has risen by the heat radiation from the circulating water pipe 138 and further cool by the cooler 137, the refrigerant 135 flowing into the case 130 can always be kept in a low temperature state. . Further, since a structure for cooling the phosphor 131 or the like is not disposed between the phosphor 131 and the excitation energy source 72, the phosphor 131 can sufficiently absorb the excitation light and emit light. Further, since a reflection layer 134 is formed on the inner surface of the case 130 excluding the excitation light transmission part 132 and the light emission transmission part 133, the coolant 135 flows in order to effectively cool the phosphor 131. Even when the internal volume is increased, the excitation light beam and the emitted light from the phosphor 131 are reflected and guided to the light-transmitting / transmitting portion 133 side. Can emit light brightly. Thus, the phosphor 131 is efficiently cooled to suppress a decrease in the luminous efficiency of the phosphor 131, and the light emitting device 64 capable of maintaining high performance over a long period of time and a plurality of light emitting devices 64 are configured. The light source device 63 and the projector 10 including the light source device 63 can be provided.

  In the projector 10, the light source device 63 built in the projector 10 is composed of three light emitting devices 64R, 64G, and 64B that can emit light in the wavelength bands of red, green, and blue. The optical axis of the light-emitting device 64 is made the same as the optical axis of the light guide device 75 by the optical axis conversion device, so that the refrigerant 135 of each light-emitting device 64 is circulated by the pump 136 and the excitation energy source of each light-emitting device 64 When the excitation light beams emitted from 72 are sequentially blinked, the red, green, and blue wavelength band lights emitted from the light-emission and transmission unit 133 of the case 130 are sequentially incident on the light guide device 75, and the excitation energy sources 72 are irradiated. In accordance with the timing, the display element 51 of the projector 10 displays the light of each color in a time-sharing manner according to the data, so that a color image can be generated on the screen.

  Each light-emitting device 64 is not limited to being configured to sequentially blink by the light source control circuit 41, and may be combined to synthesize each color light and irradiate the light guide device 75. For example, if each color light is simultaneously emitted from the red, green, and blue light emitting devices 64R, 64G, and 64B, the light guide device 75 is irradiated with white light formed by combining the respective color lights, thereby improving the luminance. it can. Furthermore, it is also possible to easily adjust the hue such as the color composition by changing the lighting time ratio of red, green, and blue to increase the lighting time of a low-luminance color.

  In addition, since a dichroic layer 133a that reflects the excitation light beam and transmits the light emitted from the phosphor 131 is formed in the light transmission portion 133, it is possible to reflect the excitation light beam and irradiate the phosphor 131. Therefore, the utilization efficiency of the excitation light beam can be improved, and the excitation light beam can be prevented from being emitted toward the light guide device 75 and emitted outside the projector 10.

  Further, by forming the dichroic layer 132a that transmits the excitation light beam and reflects the emitted light from the phosphor 131 to the excitation light beam transmitting portion 132, the emitted light from the phosphor 131 is reflected to the light guide device 75 side. Thus, the amount of light incident on the light guide device 75 can be increased.

Further, since the non-reflective coating layer is formed on the excitation light incident surface of the excitation light transmission part 132, the utilization efficiency of the excitation light emitted from the excitation energy source 72 can be improved.

  Furthermore, by adopting a light emitting diode or laser light emitter as the excitation energy source 72, power consumption can be suppressed and miniaturization can be achieved as compared with a projector using a conventional discharge lamp or the like as a light source device.

  Further, the light emitting device 64 is not limited to the case where the light emitting device 64 is composed of three light emitting devices 64 that generate light in the wavelength bands of red, green, and blue, which are the three primary colors of light, and various combinations can be employed. For example, a light-emitting device 64 that generates complementary wavelength band light such as yellow may be further incorporated into the light source device 63. Thereby, the luminance of the light source device 63 can be increased to improve the color reproducibility.

  And the arrangement position of the phosphor 131 and the arrangement position of the entrance / exit of the circulating water pipe 138 are not limited to the case where the phosphor 131 is arranged on the excitation light transmitting section 132, as shown in FIG. Various forms can be adopted.

  For example, as shown in FIG. 6, the phosphor 131 may be arranged so as to divide the case 130 into an excitation light transmission part 132 side and a light emission transmission part 133 side. At this time, the excitation light transmitting part 132 side and the light transmitting part 133 side of the case 130 are each watertight. In this case 130, the inlet / outlet of the circulating water pipe 138 is provided on each of the excitation light transmission part 132 side and the light emission transmission part 133 side.

  The light emitting device 64 is configured such that the inlet portion of the circulating water pipe 138 is formed at a predetermined angle in the same manner as described above, and the jet flow of the inflowing refrigerant 135 strikes both surfaces of the phosphor 131. Thereby, since the phosphor 131 can be efficiently cooled from both sides, the performance can be maintained for a longer period. In order to cool more effectively, for example, the flow of the refrigerant on the side of the light transmission part 133 in FIG. 6 is reversed, and the direction of the flow of the refrigerant on each of the excitation light transmission part 132 side and the light emission transmission part 133 side is reversed. May be configured to face each other.

  In addition, as shown in FIG. 7, the phosphor 131 may be disposed substantially at the center of the case 130, and a flow path may be formed around the phosphor 131. The case 130 of the light emitting device 64 is configured such that the phosphor 131 is held by a lattice and the refrigerant 135 can pass through the gap of the lattice.

  The light emitting device 64 is configured such that a part of the refrigerant 135 flows from the periphery of the phosphor 131 to the side of the light transmission portion 133 so that the jet flow of the refrigerant 135 that is introduced strikes one surface of the phosphor 131. It is configured to go around the body 131, return from the periphery of the phosphor 131 to the excitation light transmitting part 132 side, and flow out from the exit part.

  Accordingly, the light emitting device 64 can be made compact by using one entrance and exit for the circulating water pipe 138, and the phosphor 131 can be efficiently cooled.

  In addition, the position of the outlet of the circulating water pipe 138 is not disposed so as to face the position of the inlet depending on conditions such as the speed of the refrigerant 135 that flows in and the size of the case 130, but is disposed on the light transmission portion 133 side. Sometimes.

  In addition, without arranging the entrance and exit of the circulating water pipe 138 one by one, it is provided on each of the excitation light transmitting part 132 side and the light emitting transmission part 133 side with respect to the arrangement position of the phosphor 131, and on both sides of the phosphor 131. Cooling efficiency can also be improved by direct cooling by applying the jet flow of the refrigerant 135.

  And this invention is not limited to the above Example, A change and improvement are possible freely in the range which does not deviate from the summary of invention. For example, the light emitting device 64 is not limited to the case where the cooler 137 is provided, and the refrigerant 135 can be cooled by heat radiation from the circulating water pipe 138 formed of copper, aluminum, or the like having high thermal conductivity. . In this case, the circulation water pipe 138 is preferable because it is formed long and the cooling efficiency can be improved by blowing air from the cooling fan onto the outer surface.

  Further, the blower that blows air to the coolers 137 is not limited to a cooling fan disposed in a device such as the projector 10, and may be individually attached to each cooler 137. Further, a reservoir tank may be provided in the circulation path so that the refrigerant 135 can be easily taken in and out.

  Further, with respect to the excitation light transmission part 132 and the light emission transmission part 133 formed in the case 130 of the light emitting device 64, the excitation light transmission part 132 is formed on one surface, and the excitation energy source 72 is formed on the other surface facing each other. The light transmission part 133 is formed so that the optical axis of the light source and the optical axis of the light emitted from the light emitting device 64 are the same. The part 133 may be formed in a shifted manner, or one of the parts 133 may be formed on the side surface instead of the facing surface.

  Since the excitation energy source 72 only needs to be disposed at a position where the excitation light transmission unit 132 can irradiate, the optical axis of the excitation light beam from the excitation energy source 72 is set to the excitation light transmission unit 132. Without being limited to the case of being arranged so as to be orthogonal to the surface, it may be arranged so that the excitation light beam is incident at a predetermined angle.

  The light source device 63 mounted on the projector 10 is not limited to the case where a plurality of light emitting devices 64 are arranged, but a single white light emitting device 64 having a phosphor 131 that can generate white wavelength band light. The white light from the white light emitting device 64 can be colored with a color wheel. Thereby, the design freedom of the projector 10 can be improved.

  Further, the light emitting device 64 of the above embodiment is incorporated in the projector 10 with the light transmission / transmission portion 133 being about several centimeters. However, the light emitting device 64 is not limited to being mounted on the projector 10 and can be applied to various devices such as an exposure device. It can be mounted and used. The light-emitting device 64 is not limited to the combination of red, green, and blue, but includes a large number of single-color light-emitting devices 64 by incorporating the light-emitting device 64 that emits a single color into the lighting device. It can also be used by being mounted on various illumination devices and display devices such as an illumination illumination device, an illumination device capable of irradiating a monochromatic spotlight, an illumination device as a surface light source, and an illumination device as a backlight of a liquid crystal panel.

  And, the excitation energy source 72 is not limited to those capable of emitting ultraviolet light as invisible light or wavelength range light such as violet as visible light, and uses higher energy as the excitation light, An excitation energy source 72 that can emit X-rays and electron beams can also be employed. In this case, the traveling direction of the emitted light from the phosphor 131 is changed by 90 degrees using a mirror, a prism, or the like, and a shield such as a shield plate is provided in the direction from the excitation energy source 72 to the phosphor 131 to the end of the mirror, prism, or the like. To obtain high brightness light.

10 Projector 11 Top panel
12 Front panel 13 Back panel
14 Right panel 15 Left panel
17 Exhaust hole 18 Intake hole
19 Lens cover 20 Various terminals
21 I / O connector 22 I / O interface
23 Image converter 24 Display encoder
25 Video RAM 26 Display driver
31 Image compression / decompression unit 32 Memory card
35 Ir receiver 36 Ir processor
37 Key / Indicator section 38 Control section
41 Light source control circuit 43 Cooling fan drive control circuit
45 Lens motor 47 Audio processor
48 Speaker 51 Display element
53 Display element cooling device 62 Light source side optical system
63 Light source device 64 Light emitting device
64R Red light emitting device 64G Green light emitting device
64B Blue light emitting device 70 Optical system unit
72 Excitation energy source 74 Optical axis change mirror
75 Light guide device 78 Illumination side block
79 Image generation block 80 Projection side block
84 Irradiation mirror 90 Projection side optical system
93 Fixed lens group 97 Movable lens group
101 Power circuit block 102 Light source control circuit board
103 Control circuit board 110 Blower
111 Suction port 113 Discharge port
114 Exhaust temperature reduction device 120 Partition wall
121 Inlet side space 122 Exhaust side space
130 Case 131 Phosphor
132 Excitation light transmission part 132a Dichroic layer
133 Emission transmission part 133a Dichroic layer
134 Reflective layer 135 Refrigerant
136 Pump 137 Cooler
138 Circulating water pipe 139 O-ring
140 Reflection mirror 141 Dichroic mirror
141a 1st dichroic mirror 141b 2nd dichroic mirror
148 Lens group 163 Convex lens
164 Light guiding device incident lens

Claims (8)

A phosphor that receives excitation light and emits light in a predetermined wavelength range;
An excitation energy source for irradiating the phosphor with an excitation beam;
A case having an excitation light transmissive part for injecting an excitation light beam from the excitation energy source, and a light emission transmissive part for emitting the wavelength band light emitted from the phosphor;
With
The light emitting device, wherein the phosphor is disposed in the case, and an inlet portion of the refrigerant is formed at a predetermined angle so that the refrigerant is directed toward the surface of the phosphor.   The light emitting device according to claim 1, wherein the phosphor is arranged at a position where an ejected flow of the refrigerant flowing into the case hits at least one surface of the phosphor. A circulation path connected to the case and the pump,
2. The light emitting device according to claim 1, wherein the inlet / outlet of the circulation path is provided on each of the excitation light transmitting portion side and the light emitting transmitting portion side with respect to the arrangement position of the phosphor. The light emitting device according to any one of claims 1 to 3, further comprising a cooler that cools the refrigerant. The excitation energy source can emit visible light or ultraviolet light as an excitation light beam, and the light-emitting transmission part reflects the excitation light beam and transmits a wavelength band light emitted from the phosphor. The light emitting device according to claim 1, wherein the light emitting device is formed. 6. The light emitting device according to claim 5, wherein a dichroic layer that transmits the excitation light beam and reflects the wavelength band light emitted from the phosphor is formed in the excitation light beam transmitting portion. .   A light source device comprising the light emitting device according to claim 1. A projector comprising the light source device according to claim 7 .

Images